NO315813B1 - Connection and method of attaching a riser to an underwater wellhead - Google Patents

Description

Technical area

This invention relates to a coupling for connecting a riser from a platform to an underwater wellhead housing, the wellhead housing having a bore with an internal groove, an inner body adapted to be attached to the riser, the inner body having an outer profile and a loading shoulder in distance below, a housing which is movably held on the inner body for placement on the wellhead, and an upper locking element which is held by the housing, the upper locking element being movable radially inwards to abut against the profiling. The invention also relates to a method for connecting a riser from a platform to an underwater wellhead, the wellhead having a bore with an internal groove, providing a coupling having an inner body, a housing which is held axially movable on the inner body and a locking element which is mounted for axial pushable movement on an inclined load shoulder on the inner body, the inner body being connected to the riser and the coupling lowered onto the wellhead, so that the inner body extends into the borehole and the housing is placed on the wellhead.

Background technology

One type of subsea well makes use of a wellhead housing located at the seabed and a drill blowout preventer or production valve tree located at the surface on a platform. Large-diameter casing is lowered from the platform and connected to the wellhead housing with a connection coupling. The connecting link must withstand various load conditions that may occur during prolonged periods of operation. Particularly from a tie rod platform where the upper end of the riser is allowed to move horizontally, a bending moment occurs at the wellhead. This can occur even with a fixed platform where there is significant flow force acting on the riser. The connection with the wellhead must also be able to withstand significant vertical force, either as pressure when not the entire load is carried by the platform, or as tension when a large load is carried by the platform. In addition, thermal expansion occurs in the riser and wellhead depending on whether the well is producing and the temperature of the fluid being produced. Furthermore, the riser must withstand these stresses through many cycles over several years.

One type of coupling has a downward-facing funnel that is pushed over the wellhead housing. It has a body with an internal coupling device with carriers that engage against grooves formed in the wellhead housing. The coupling is preloaded on the wellhead housing by forcing the drivers into the grooves and requires a high operating force to achieve a high preload. The carriers resist all compressive and tensile loads transferred from the riser to the wellhead. These connections have a high capacity in terms of load and separation, but has a large outer diameter. In many cases, a reduced diameter is desired, such as for use on a tie rod platform.

US 5,775,427 describes one attachment coupling for connecting a riser to a wellhead housing, the coupling having an outer body and an inner body located inside the outer body. An actuating piston is hydraulically actuated to move a rounded end of the piston into engagement with a snap ring, which is supported by a reaction ring and an adjusting ring. This forces the snap ring into the recess on the inner surface of the wellhead housing. The inner body remains stationary relative to the wellhead housing while the piston is moved. The resulting preload is generated as the snap ring engages the recess, with subsequent compression and deformation of the rounded end, an upper portion of the piston, and the adjusting ring.

NO 304,036 describes a coupling for connecting pipe parts such as an outer pipe part and an inner pipe part. A locking ring surrounds a lower part of the inner tube part, the locking ring comprising a lower inner cam and an upper outer cam. A wedge ring surrounds an upper portion of the inner tube portion and is prevented from upward movement by a shoulder. The wedge ring supports a locking ring, and a second wedge ring is placed over the locking ring. As the inner tube member is lowered into the outer tube member, the lower cam engages a lower groove on the inner tube member before the shoulder on the lower end of the snap ring is placed on the mounting seat of the outer tube member. After placement, the locking ring is moved upwards, while the lower cam is moved into the upper slot. The downward movement of the inner tube section causes the upper cam to be wedged outwards against the mounting shoulder. A pipe fitting tool is used to move the second key ring down to key the locking ring into engagement with the upper internal shoulder. The inner tube part does not move upwards during installation.

Although designs similar to these have achieved recognition, improvements are desired in terms of increase in static strength and preload capacity to increase the coupling's resistance in terms of separation loads.

Summary of the invention

The coupling according to the present invention is characterized by the fact that the profiling is designed to move the inner body upwards relative to the housing when it is in contact with the upper locking element, that a cam sleeve is held on the inner body for axial movement relative to the inner body, which forces the locking element inwards to contact the profiling on the inner body, and that a locking element with a load transfer part is held on the inner body in displaceable abutment against the load shoulder, the load transfer part being adapted to move radially outwards and to abut against the inner track when the inner body and the load shoulder are moved upwards relative to the housing.

Furthermore, the coupling preferably comprises a piston element which cooperates with the cam sleeve to define a hydraulic fluid chamber. The chamber is arranged to receive hydraulic pressure fluid to push the cam sleeve axially. The outer profile preferably exhibits a downward sloping shoulder. It is preferred that the locking element has several carriers. It is also preferred that the housing has essentially the same outer diameter as the wellhead housing, and is located on an edge of the wellhead housing. Preferably, the locking element has several segmented fingers. Each finger has a finger extending upwards from the load transfer part. The finger has an outer projecting portion on an upper end which engages with a recess in the housing. The finger has an inner surface which is in contact with the inner body when the inner body is moved upwards to an upper position. The locking element has a surface that rests downwards on the housing while the cam sleeve is guided axially to exert a preload force on the wellhead by pushing the housing down on top of the wellhead while pulling up the inner housing.

The method according to the invention is characterized by the fact that the inner body is moved upwards relative to the housing to an upper position while upward movement of the locking element is restrained, which causes the locking element to be pushed radially outwards onto the load shoulder and into a facility with a groove in the wellhead which prevents further upward movement of the inner body, while applying a downward force on the housing against the wellhead and the inner body is locked in the upper position.

Preferably, force is applied to the housing, while the inner body is moved up and down, with hydraulic pressure in a chamber between the inner body and the housing. It is also preferred that the locking comprises pushing a locking element, held by the housing, radially inwards towards a profile on the inner body. The locking element is pushed radially inward by movement of a cam sleeve axially.

The invention has many significant advantages. Because the coupling is fitted with an inner groove on the wellhead, instead of an outer groove, the coupling can have a relatively small outer diameter that is the same size or only slightly larger than the high-pressure wellhead housing. Consequently, smaller openings are required in the air containers and the keel opening for carrying out this connection can be smaller. Furthermore, the forgings required to form the coupling can be smaller and thus less expensive than larger couplings. The coupling provides push-in force using the weight of the riser. Additional preload can be applied hydraulically by an ROV. Consequently, the coupling according to this invention can cause a higher preload than other conventional internal couplings and achieve the separation capacities of some of the larger external couplings.

Brief description of the drawings

Fig. 1 is a sectional view of an attachment coupling constructed in accordance with

this invention, before preload.

Fig. 2 is the connection coupling according to fig. 1 during assembly.

Fig. 3 is the attachment coupling according to fig. 1 after completion of assembly.

Description of an embodiment of a coupling according to the invention

With reference to fig. 1-3 shows an assembly plan for the inner connection coupling 10. A mandrel or an inner body 12 has an upper end attached to a tension connection for risers (not shown). The inner body 12 extends just below the tapered portion of the tension connection. At the bottom of the inner body 12 is a centering element 13 with a U-seal of metal or a seal 14 for the wellhead housing with an associated spacer 16 and a nose piece 18 which retains the housing seal 14. A multi-bundle safety seal 20 is also incorporated just above the U - the seal 14 of metal. These seals are designed to engage and form a seal in the bushing or shark section 22 of the casing hanger 24.

Approximately one-third up from the bottom of the length of the inner body 12, a groove 26 is formed in the outer surface of the inner body 12. Several locking elements 30 each having a load transfer part 31 are held around the inner body 12 with the load transfer part in displaceable contact with the load shoulder 33. A split locking ring or holder 28 is located in a groove in the upper end of the locking element 30 to retain the locking element 30. The holder 28 drives the upper ends of the locking elements 30 outwards. A lower splitting ring 29 drives the locking elements 30 inwards into the load shoulder 33.

An upper U-seal 32 of metal is connected to the inner body 12 just above the locking ring 28 and held in place by a seal holder 34. The upper U-seal 32 of metal is used to form a seal for a housing 36 in the attachment coupling 10. A Multi-bundle fuse 38 is also provided at this location. This housing 36 is located on the edge of the high-pressure wellhead housing or outer housing 40 where pressure loads from both external loads and the preload are transferred back into the outer housing 40. The housing 36 also provides a metal seal for the outer housing 40 through the use of a VX or VT gasket 42 of metal. The outer housing 40 has an inner groove 41 which engages with a profile on the locking elements 30. The seal 42 is retained by a set of holders 44 of the set screw type. The housing 36 also has an internal groove 46 for retaining the locking elements 30. The split ring 28 drives the upper ends of the locking elements 30 into the slot 46. The inner body 12 has a shoulder 47 just below the head of the locking element 30. The housing 36 also contains a test opening 48

for pressure testing the annulus between the inner body 12 and the outer wellhead housing 40.

An upper locking element, e.g. several carriers 50 are used to engage and preload the inner body 12 and the housing 36 of the wellhead hanger 24. The carriers 50 are located on top of the housing 36 and are in contact with a profile 52 with grooves on the outside of the inner body 12 when they are forced inward. When the carriers 50 are not in contact with the profile 52 with grooves, they are located just above the profile 52. The tapered surface between the carriers 50 and the inner body 12 causes an axial force between the carriers 50 and the inner housing 12 when the carriers 50 are forced into the grooves 52. The axial load on the carriers 50 is transferred to the top of the wellhead housing 40. At the same time, the load on the inner body 12 from the carriers 50 tries to pull the inner body upwards, where it will possibly be influenced into the wellhead housing 40 via the blocking elements 30.

The drivers 50 are activated (forced radially inward) by a cam ring 54 which is integrated into a cam sleeve 56 with a cylindrical bore 58. The cam sleeve 56 is connected to the housing 36 through a split retaining ring 60 located at the bottom of the cam sleeve 56. The lower part of the cam sleeve 56 extends over the housing 36. Elastomeric seals 64 are arranged between the interface surfaces of the housing 36, as well as both the inner body 12 and the cam sleeve 56. A piston 68 is reciprocally held in the bore 58. The piston 68 has a sleeve 66 firmly attached to the inner body 12. A top washer 70 is bolted to the top of the cam sleeve 56 and is displaceably in contact with the piston 68. A chamber 74 is formed between the cam sleeve 56 and the piston 68.

Hydraulic actuation fluid is supplied to the chamber 74 below the piston 68 through a series of ports 76 through the cam sleeve 56 and the top disc 70. The ports 76 are hydraulically connected to ROV operated valves (not shown) on the top disc 70. The ROV operated valves are used to select the hydraulic function to be performed. The valves are hydraulically connected to a hydraulic ROV "hot stab" (a tube, not shown) for supplying the activation fluid. This "hot stab" is also mounted on the top disc 70 and moves with it like the ROV-operated valves during activation. 1 in the event that mechanical override becomes necessary, two release sockets (not shown) are arranged for fastening the lifting lines. These cups are attached to the top disk 70 so that they can receive the cam sleeve 56 for release of the carriers 50. Secondary locking segments can be provided by the placement of vertical screws (not shown) which run through the top disk 70 and to the piston 68. These can be incorporated in their own ROV-T handle.

Fig. 1-3 shows in sequence the procedure when the connection coupling 10 is to be brought to plant with and preloaded in the high-pressure wellhead housing or the outer housing 40. Loosening the coupling takes place opposite to the connection procedure.

The connecting link 10 is guided downwards while it is in the position shown in fig. 1. The carriers 50 are out of contact with the groove 52. The load transfer part 31 on the locking elements 30 is in contact with the load shoulder 33 on the inner body. This retains the coupling 10 in the released state for screwing into the wellhead. The coupling 10 is lowered into the outer housing 40. When the metal U-seal 14 reaches the conduit hanger, a force of 44.4 - 66.6 kN is typically required to insert the metal U-seal 14. This force is provided by the weight of the attachment coupling 10 and the tension connection.

The connection coupling 10 will form a connection against the top of the wellhead housing 40 as shown in fig. 1. In this state, the locking elements 30 are positioned so that they are aligned inside the groove 26 in the inner body 12. The chamber ring 54 is upwards in this state, enabling the lock carriers 50 to remain outside.

Hydraulic pressure is then applied to the chamber 74 below the piston 68. This causes the chamber ring to move downward relative to the piston 68. As shown in FIG. 10, this results in the drivers 50 being pushed into the groove 52 driving the housing 36 closer to the wellhead housing 40. At the same time, the inner body 12 is forced upwards relative to the wellhead housing 40 and the housing 36. The locking elements 30 do not move axially because they are held inside the groove 46. Upward movement of the inner body 12 also causes the profiling 31 of the locking elements 30 to be pushed by the load shoulder 33 into the grooves 41 in the outer housing 40, which locks the inner body 12 to the outer housing 40.

In addition, as the cam ring 54 moves downward, the drivers 50 are forced into the adapted groove 52 on the inner body 12. The tapers of the drivers 50 and the groove 52 exert a downward force against the housing 36, which acts on the top of the wellhead housing 40 and the seal 42. This downward force is counteracted by the upward force on the inner body 12, which produces a large preload force between the wellhead housing 40 and the connecting coupling 10. The VX packing 42 is also installed in this procedure. The VX gasket 42 together with the upper U-seal 32 form a seal for the annulus between the outer housing 40 and the inner body 12. This assembled position is shown in fig. 3. Pressure can be maintained in the activation chamber 74 and a set of secondary locking screws can be driven in. The annulus pressure can be monitored at any time after locking the coupling by inserting the monitoring sensor and opening the pressure valve in the test opening. It is recommended that the annulus valve (not shown) be open during operation to prevent a pressure lock. The valve is closed after testing.

Release of the clutch is accomplished by depressurizing the lower side of the chamber 74 while applying pressure to the bore 58 above the piston after releasing any secondary locking device. This raises the cam sleeve 56 and cam ring 54 relative to the inner body 12, which enables the carriers 50 to move out to release the inner body 12 from the carriers 50. The catch ring 60 on the lower end of the cam sleeve 56 lifts the housing 36. This action allows the inner body 12 to fall back to release the locking elements 30. The locking elements 30 can now swing back into the position shown in fig. 1, which enables the coupling to be pulled free from the outer housing 40.

Claims (13)

1. Coupling (10) for connecting a riser from a platform to an underwater wellhead housing (40), the wellhead housing having a bore with an internal groove (41), an inner body (12) adapted to be attached to the riser, the inner body (12) having an outer profiling (52) and a load shoulder (33) spaced below, a housing (36) which is movably held on the inner body (12) for placement on the wellhead (40), and an upper locking element (50) ) which is held by the housing (36), the upper locking element (50) being movable radially inwards to abut against the profiling (52), characterized in that the profiling (52) is designed to move the inner body (12) upwards relative to the housing (36) when it is in contact with the upper locking element (50), that a cam sleeve (56) is held on the inner body (12) for axial movement relative to the inner body (12), which forces the locking element (50) inwards to abut against the profiling (52) on the inner body (12), and that a blocking element (30) with a load transfer part (31) is held on the inner body (12) in sliding contact with the load shoulder (33), the load transfer part (31) being adapted to move radially outwards and to abut against the inner groove (41) when the inner body (12) and the load shoulder (33) are moved upwards relative to the housing (36). 2. Coupling (10) according to claim 1, characterized by a piston element (68) which cooperates with the cam sleeve (56) to define a hydraulic fluid chamber adapted to receive hydraulic fluid pressure to move the cam sleeve (56) axially. 3. Coupling (10) according to claim 1, characterized in that the profiling (52) comprises a downward sloping shoulder. 4. Coupling (10) according to claim 1, characterized in that the locking element (50) comprises several carriers. 5. Coupling (10) according to claim 1, characterized in that the housing (36) mainly has the same outer diameter as the wellhead housing and is placed on an edge of the wellhead housing (40). 6. Coupling (10) according to claim 1, characterized in that the locking element (30) comprises several fingers, each having a finger that extends upwards from the load transfer part (31), and that the finger has an outer protruding part on an upper end which is in contact with a recess (46) in the housing (36). 7. Coupling (10) according to claim 1, characterized in that a centering pin (13) on a lower end of the inner body (12) is adapted to be in contact with a bushing (22) on a casing hanger (24) in the wellhead housing (40) . 8. Coupling (10) according to claim 1, characterized in that the locking element (50) has a surface that bears downwards on the housing (36) while the comb sleeve (56) moves axially to exert a preload force on the wellhead housing (40). 9. Method for connecting a riser from a platform to an underwater wellhead (40), the wellhead (40) having a bore with an internal groove (41), providing a coupling (10) having an inner body (12) , a housing (36) held axially movably on the inner body (12) and a locking element (30) mounted for axially slidable movement on an inclined load shoulder (33) on the inner body (12), the inner body (12) being connected to the riser and the coupling (10) is lowered onto the wellhead (40), so that the inner body (12) extends into the borehole and the housing (36) is placed on the wellhead (40), characterized in that the inner body (12) is moved upwards relative to the housing (36) to an upper position while upward movement of the locking element (30) is restrained, which causes the locking element (30) to be pushed radially outwards onto the load shoulder (33) and into contact with the groove (41) in the wellhead (40) which prevents further upward movement of the inner body (12), while a downward force is applied to the housing (36) against the wellhead (40) and the inner body (12) is locked in the upper position. 10. Method according to claim 9, characterized in that while the inner body (12) is moved upwards and downwards, force is applied to the housing (36) with hydraulic pressure in a chamber between the inner body (12) and the housing (36). 11. Method according to claim 9, characterized in that locking the inner body (12) in the upper position comprises a locking element (50) which is held by the housing (36) being pushed radially inwards into a profiling (52) on the inner body (12). 12. Method according to claim 11, characterized in that the locking element (50) is pushed radially inward by movement of a cam sleeve (56) axially. 13. Method according to claim 9, characterized in that a centering part (13) on a lower end of the inner body (12) is introduced into a bush rod (22) on a casing hanger (24) in the wellhead (40).